Semiconductor device with an electrically-coupled protection mechanism and associated systems, devices, and methods

ABSTRACT

A semiconductor device includes a first die; a first metal enclosure directly contacting and vertically extending below the first die, wherein the first metal enclosure peripherally encircles a first enclosed space; a second die directly contacting the first metal enclosure opposite the first die; a second metal enclosure directly contacting and vertically extending below the second die, wherein the second metal enclosure peripherally encircles a second enclosed space; and an enclosure connection mechanism directly contacting the first metal enclosure and the second metal enclosure for electrically coupling the first metal enclosure and the second metal enclosure.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.15/878,725, filed Jan. 24, 2018, which is incorporated herein byreference in its entirety.

This application contains subject matter related to a previously-filedU.S. Patent Application by Wei Zhou, Bret Street, and Mark Tuttle titled“SEMICONDUCTOR DEVICE WITH A PROTECTION MECHANISM AND ASSOCIATEDSYSTEMS, DEVICES, AND METHODS.” The related application is assigned toMicron Technology, Inc., and is identified by application Ser. No.15/693,230, filed Aug. 31, 2017. The subject matter thereof isincorporated herein by reference thereto.

This application contains subject matter related to an U.S. PatentApplication by Wei Zhou and Bret Street titled “SEMICONDUCTOR DEVICEWITH A LAYERED PROTECTION MECHANISM AND ASSOCIATED SYSTEMS, DEVICES, ANDMETHODS”. The related application is assigned to Micron Technology,Inc., and is identified as U.S. application Ser. No. 15/878,755, filedJan. 24, 2018. The subject matter thereof is incorporated herein byreference thereto.

TECHNICAL FIELD

The present technology is related to semiconductor devices, and, inparticular, to semiconductor devices with an electrically-coupledprotection mechanism.

BACKGROUND

Semiconductor devices dies, including memory chips, microprocessorchips, and imager chips, typically include a semiconductor die mountedon another structure (e.g., a substrate, another die, etc.) and encasedin a plastic protective covering. The die includes functional features,such as for memory cells, processor circuits, and imager devices, aswell as interconnects that are electrically connected to the functionalfeatures. The interconnects can be electrically connected to terminalsoutside the protective covering to connect the die to higher levelcircuitry.

As illustrated in FIG. 1, a semiconductor device 100 (e.g., a threedimensional interconnect (3DI) type of device or a semiconductor packagedevice) can include a die 102 having die interconnects 104 thereonconnected to a substrate structure 106 (e.g., a printed circuit board(PCB), a semiconductor or wafer-level substrate, another die, etc.)having substrate interconnects 108 thereon. The die 102 and thesubstrate structure 106 can be electrically coupled to each otherthrough the die interconnects 104 and the substrate interconnects 108.Further, the die interconnects 104 and the substrate interconnects 108can be directly contacted each other (e.g., through a bonding process,such as diffusion bonding or hybrid bonding) or through an intermediatestructure (e.g., solder). The semiconductor device 100 can furtherinclude an encapsulant, such as an underfill 110, surrounding orencapsulating the die 102, the die interconnects 104, the substratestructure 106, the substrate interconnects 108, a portion thereof, or acombination thereof.

With technological advancements in other areas and increasingapplications, the market is continuously looking for faster and smallerdevices. To meet the market demand, physical sizes or dimensions of thesemiconductor devices are being pushed to the limit. For example,efforts are being made to reduce a separation distance between the die102 and the substrate structure 106 (e.g., for 3DI devices anddie-stacked packages).

However, due to various factors (e.g., viscosity level of the underfill110, trapped air/gases, uneven flow of the underfill 110, space betweenthe interconnects, etc.), the encapsulation process can be unreliable,such as leaving voids 114 between the die 102 and the substratestructure 106 (e.g., with portions of the interconnects failing todirectly contact the underfill 110). The voids 114 can cause shortingand leakage between the interconnects (e.g., between the substrateinterconnect 108 and/or between the die interconnects 104), causing anelectrical failure for the semiconductor device 100. Further, as thedevice grows smaller, the manufacturing cost can grow (e.g., based onusing nano-particle underfill instead of traditional underfill).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of a semiconductor device.

FIG. 2 is a cross-sectional view along a line 2-2 in FIG. 3 of asemiconductor device in accordance with an embodiment of the presenttechnology.

FIG. 3 is a cross-sectional view along a line 3-3 in FIG. 2 of asemiconductor device in accordance with an embodiment of the presenttechnology.

FIG. 4 is a cross-sectional view of a semiconductor device in accordancewith an embodiment of the present technology.

FIG. 5 is a cross-sectional view of a semiconductor device in accordancewith an embodiment of the present technology.

FIG. 6 is a cross-sectional view of a semiconductor device in accordancewith an embodiment of the present technology.

FIG. 7 is a cross-sectional view of a semiconductor device in accordancewith an embodiment of the present technology.

FIGS. 8-11 are cross-sectional views illustrating a semiconductor deviceat selected stages in a manufacturing method in accordance with anembodiment of the present technology.

FIG. 12 is a flow diagram illustrating an example method ofmanufacturing a semiconductor device in accordance with an embodiment ofthe present technology.

FIG. 13 is a flow diagram illustrating a further example method ofmanufacturing a semiconductor device in accordance with an embodiment ofthe present technology.

FIG. 14 is a block diagram illustrating a system that incorporates asemiconductor device in accordance with embodiments of the presenttechnology.

DETAILED DESCRIPTION

The technology disclosed herein relates to semiconductor devices,systems with semiconductor devices, and related methods formanufacturing semiconductor devices. The term “semiconductor device”generally refers to a solid-state device that includes one or moresemiconductor materials. Examples of semiconductor devices include logicdevices, memory devices, and diodes, among others. Furthermore, the term“semiconductor device” can refer to a finished device or to an assemblyor other structure at various stages of processing before becoming afinished device. Depending upon the context in which it is used, theterm “substrate” can refer to a structure that supports electroniccomponents (e.g., a die), such as a wafer-level substrate or asingulated die-level substrate, another die for die-stacking or 3DIapplications, or a printed circuit board (PCB). A person having ordinaryskill in the relevant art will recognize that suitable steps of themethods described herein can be performed at the wafer-level or at thedie level. Furthermore, unless the context indicates otherwise,structures disclosed herein can be formed using conventionalsemiconductor-manufacturing techniques. Materials can be deposited, forexample, using chemical vapor deposition, physical vapor deposition,atomic layer deposition, spin coating, and/or other suitable techniques.Similarly, materials can be removed, for example, using plasma etching,wet etching, chemical-mechanical planarization, or other suitabletechniques.

Many embodiments of the present technology are described below in thecontext of protecting the semiconductor dies and the associatedelectrical connections and further utilizing the protection structure torelay electrical signals. For example, semiconductor devices (e.g., 3DIpackaging solutions) can each include a semiconductor die with dieinterconnects thereon connected to a substrate structure (e.g., a PCB oranother die). To protect the die and the die interconnects (e.g.,against environmental factors, such as moisture, debris, etc.), thesemiconductor devices can each include a metal (e.g., copper, aluminum,alloy, etc.) enclosure that surrounds the die interconnects along ahorizontal plane. The metal enclosure can further extend verticallybetween and/or directly contact the die and the substrate to enclose thedie interconnects. As such, the semiconductor devices can use the metalenclosure instead of any encapsulants (e.g., underfills) to isolate thedie interconnects from surrounding exterior space and/or environment.

Further, the metal enclosure can be electrically coupled to conductelectrical signals or an electrical potential (e.g., for providing aground connection or a source voltage). The metal enclosure can beelectrically coupled using one or more through-silicon vias (TSVs), aconductive paste, one or more wires (e.g., bond wires), or a combinationthereof. In some embodiments, the metal enclosure can be connected to(e.g., via a direct contact or through another conductor) anelectro-magnetic interference (EMI) shield.

As used herein, the terms “vertical,” “lateral,” “upper” and “lower” canrefer to relative directions or positions of features in thesemiconductor die assemblies in view of the orientation shown in theFigures. For example, “upper” or “uppermost” can refer to a featurepositioned closer to the top of a page than another feature. Theseterms, however, should be construed broadly to include semiconductordevices having other orientations, such as inverted or inclinedorientations where top/bottom, over/under, above/below, up/down andleft/right can be interchanged depending on the orientation.

FIG. 2 is a cross-sectional view along a line 2-2 in FIG. 3 of asemiconductor device 200 (e.g., a semiconductor die assembly, includinga 3DI device or a die-stacked package) in accordance with an embodimentof the present technology. The semiconductor device 200 can include oneor more semiconductor dies mounted on or connected to a substrate (e.g.,another die or a PCB). For example, the semiconductor device 200 caninclude a die stack 202 including a first die 212 connected on top of asecond die 214. In some embodiments, the die stack 202 can furtherinclude one or more inner dies 216 between the first die 212 and thesecond die 214.

The dies in the semiconductor device 200 can be electrically connectedthrough metal or conductive interconnects. For example, the first die212, the second die 214, the inner dies 216, or a combination thereofcan be connected to each other and/or another structure (e.g., a PCB oranother device) using internal interconnects 218. In some embodiments,the internal interconnects 218 can be structures resulting from bondingor joining (e.g., such as through diffusion bonding or hybrid bonding)pillars, pads, or interconnect structures protruding from or exposed ata first boundary surface 222 (e.g., one of the surfaces of the dies,such as a bottom surface) to the corresponding structures protrudingfrom or exposed at a second boundary surface 224 (e.g., an opposingsurface of a die or a PCB facing the first boundary surface 222, such asa top surface of a connected or an adjacent die or PCB). The firstboundary surface 222 and the second boundary surface 224 can function asboundaries (e.g., such as top and bottom boundary planes) for aninternal space 226 (“enclosed space 226”) between the dies, between thedie and the PCB, or a combination thereof.

The semiconductor device 200 can further include metal (e.g., copper,aluminum, alloy, etc.) enclosure structures 220 (“enclosures 220”) thatcontinuously surrounds or encloses the internal interconnects 218 alonga horizontal plane. The enclosures 220 can each be a continuous andsolid metallic (e.g., copper and/or solder) structure that forms a wallperipherally surrounding the internal interconnects 218. The enclosures220 can further extend from and directly contact the first boundarysurface 222 to and the second boundary surface 224. In some embodiments,the enclosures 220 (e.g., solid copper and/or solder structures) can beformed through a bonding process (e.g., diffusion bonding, thermalcompression bonding, mass reflow, etc.). In some embodiments, theenclosures 220 can each have a vertical dimension or a height that isless than or equal to 20 μm. In some embodiments, the enclosures 220 caninclude solder that can be bonded through thermal compression bonding ormass reflow.

Each of the enclosures 220 can function as horizontal or peripheralboundaries (e.g., such as vertical planes marking peripheral edges alonga horizontal plane) of the enclosed space 226. The enclosed space 226can be vacuum or filled with inert or specific gas (e.g., without anyencapsulant material or underfill therein). Accordingly, the enclosures220 can isolate the internal interconnects 218 from external space onthe outside of the enclosures 220.

In some embodiments, an outer surface of the enclosures 220 can belocated at an edge offset distance 228 (e.g., a distance measured alonga horizontal direction) from a die periphery edge 230. In someembodiments, the enclosures 220 can be located such that an edge or asurface thereof is coplanar or coincident with the die periphery edge230 along a vertical plane or line (e.g., where the edge offset distance228 is 0). In some embodiments, the enclosures 220 can be located suchthat a peripheral portion thereof horizontally extends beyond the dieperiphery edge 230.

For the semiconductor device 200, the enclosures 220 can further provideelectrical connections for one or more of the dies, structures, and/ordevices therein. For example, the enclosures 220 can be connected (e.g.,through direct contact and/or through another electrical conductor, suchas a trace) to one or more TSVs, such as periphery TSVs 242 (e.g., oneor more TSVs located on periphery portions of the correspondingsemiconductor die) and/or inner TSVs 244 (e.g., one or more TSVs locatedon an inner or central portion of the corresponding semiconductor die).Also for example, one or more of the internal interconnects 218 can beconnected to (e.g., through direct contact and/or through anotherelectrical conductor, such as a trace) to one or more TSVs, such as theinner TSVs 244 and/or the periphery TSVs 242. The enclosures 220 can beconnected to electrical ground, a source voltage, or a signal.

In some embodiments, the semiconductor device 200 can further include adevice substrate 262 (e.g., a PCB) connected to one or more dies. Forexample, the device substrate 262 can be attached to the second die 214(e.g., the bottom die) of the die stack 202. The device substrate 262and the attached die can be electrically coupled through one or moreinterconnects and/or one or more metal enclosure structures (e.g., thatare connected to the TSVs of the bottom die) as discussed above.Alternatively, the device substrate 262 can be attached to the seconddie 214 using device interconnects 264 (e.g., solder) different from theinternal interconnects 218 and/or the enclosures 220. The deviceinterconnects 264 can directly contact the TSVs of the bottom die andbond pads 266 on the device substrate 262. In some embodiments, anunderfill 268 can be between the bottom die and the device substrate 262and encapsulate the device interconnects 264. In some embodiments, anenclosure can be mounted between the bottom die and the device substrate262 such that no underfill is needed.

In some embodiments, the enclosures 220 can be connected to each other(e.g., ring-to-ring and/or enclosure-to-enclosure connection) through anouter-enclosure connector, such as the periphery TSVs 242. For example,as illustrated in FIG. 2, the semiconductor device 200 can includemultiple semiconductor dies and the enclosures 220. All of the dies canbe aligned along one or more vertical lines or planes. Similarly, all ofthe enclosures can be aligned alone one or more vertical lines or planes(e.g., all of the enclosures can have same values for the edge offsetdistance 228). Accordingly, all of the dies can include the peripheryTSVs 242 at the same location and under the enclosures (e.g., shiftedfrom the edge offset distance 228, such as by a fraction of a thicknessof the enclosures 220). In some embodiments, one or more enclosures canbe further connected to the device substrate 262 (e.g.,ring-to-substrate or enclosure-to-substrate connection) through theperiphery TSVs 242 and/or the device interconnects 264.

As an illustrative example, the first die 212 can directly contact afirst metal enclosure (e.g., one instance of the enclosures 220) at abottom surface of the first die. The first metal enclosure can extendvertically downward and peripherally encircle or surround (e.g., along ahorizontal plane) a first enclosed space a first group of the internalinterconnects 218. The first metal enclosure can further directlycontact another die, such as one of the inner dies, opposite the firstdie 212. The one of the inner dies can further have a second metalenclosure directly contacting and extending vertically downward from abottom surface of thereof. The one of the inner dies can include one ormore periphery TSVs 242 that extends through the inner dies from the topsurface to the bottom surface. The one or more periphery TSVs 242 candirectly contact both the first metal enclosure and the second metalenclosure and electrically couple the metal enclosures, such as forgrounding the metal enclosures.

FIG. 3 is a cross-sectional view along a line 3-3 in FIG. 2 of asemiconductor device in accordance with an embodiment of the presenttechnology. FIG. 3 can correspond to a bottom view of the semiconductordevice 200 above the second die 214 of FIG. 2 (e.g., without showing thesecond die 214 and structures below). As discussed above, each of theenclosures 220 can encircle a periphery or a perimeter of the internalinterconnects 218 along a plane.

For illustrative purposes, the enclosure is shown having a rectangularshape, uniform thickness or width, and concentric with a shape oroutline of a corresponding die (e.g., one of the inner dies 216 of FIG.2). However, it is understood that the enclosures 220 can be different.For example, the enclosures 220 can have an oval shape, an irregular orasymmetrical shape, or any N-sided polygonal shape. Also for example,the enclosures 220 can have varying thickness or width at differentportions. Also for example, the enclosures 220 can be offset ornon-concentric with respect to the internal interconnects 218 or anarrangement thereof, the shape or outline of the die, or a combinationthereof.

The enclosures 220 provide decrease in overall size of the semiconductordevice. Because underfill is not necessary, the bond line thickness canbe reduced, leading to a very low packaging height for multiple-diestacking. Further, the semiconductor device 200 that excludes solder inthe interconnects 218 (e.g., by using a solid copper structure, such asresulting from Cu—Cu diffusion bonding) can provide a decrease inmanufacturing cost by eliminating pillar bumping. Also, thesemiconductor device 200 that exclude solder in the interconnects 218provides reduction in failure rates by providing clean joints withoutsolder caps, thereby removing failure modes associated with solderbridging, slumping, starvation, intermetallic compound (IMC),electromagnetic (EM) effect, etc.

The enclosures 220 can also provide a reduction in manufacturing costand failure rates as the package height is decreased. The enclosures 220can protect and isolate the internal interconnects 218 fromenvironmental factors (e.g., moisture, debris, etc.), which eliminatesthe need for underfills (e.g., nano-particle underfills). Accordingly,the costs and the error rates associated with underfill laminate orflowing process, both of which increases rapidly as the space betweenthe first boundary surface 222 of FIG. 2 and the second boundary surface224 of FIG. 2 decreases, can be eliminated based on using the enclosures220 to obviate the need for underfill. Further, the enclosures 220provide a joint that can provide mechanical, thermal, and electricaltraits or benefits previously provided by the underfill.

In some embodiments, the enclosures 220 throughout the die stack 202 ofFIG. 2 can be connected to each other and to the electrical groundthrough the periphery TSVs 242 of FIG. 2. Grounding the enclosuresthroughout the die stack 202 can improve the signal integrity for thedie stack 202. The grounded enclosures can provide electromagnetic orradio frequency (RF) shielding for the active signals within theenclosures.

The connected enclosures (e.g., for ring-to-ring connections and/orring-to-substrate connections) can further provide highercurrent-carrying capacity (e.g., for grounding or source voltageconnections) with reduced interference (e.g., in the form of noise orinterference) for active signals (e.g., signals through the internalinterconnects 218). The enclosures and the periphery TSVs 242 canprovide higher current-carrying capacity (e.g., in comparison to otherinterconnects) that results from increased dimensions andcurrent-carrying material corresponding to the periphery location andthe enclosing/encircling shape thereof. Further, the enclosures can bephysically spaced apart or separated from the internal interconnects218, which can decrease any noise or interference that thegrounding/power connections can have on active signals. Further, theseparation can further decrease the likelihood of failure due tounintended electrical shorts (e.g., such as due to misalignment ormisconnection, debris or bridges, etc.) between active signals, sourcevoltage, electrical ground, or a combination thereof.

FIG. 4 is a cross-sectional view of a semiconductor device 400 inaccordance with an embodiment of the present technology. Thesemiconductor device 400 can be similar to the semiconductor device 200of FIG. 2. For example, the semiconductor device 400 can includemultiple dies (e.g., such as for a die stack) with internalinterconnects providing electrical connections. Also for example, thesemiconductor device 400 can further include one or more metal enclosurestructures 420 (“enclosures 420”) between dies, between a die and adevice substrate, or a combination thereof with each enclosure enclosinga space (e.g., enclosed space) that includes the internal interconnects.The enclosed space can otherwise be vacuum or filled with inert orspecific gas. The internal interconnects, the enclosures 420, or acombination thereof can be electrically connected to (e.g., via directcontact or through a conductor) integrated circuits, bond pads, TSVs, ora combination thereof in or on the dies.

In some embodiments, the enclosures 420 can be connected to each other(e.g., ring-to-ring and/or enclosure-to-enclosure connection) through anouter-enclosure connector, such as a conductive paste 442. For example,as illustrated in FIG. 4, the semiconductor device 400 can have a filletof the conductive paste 442 directly contacting a periphery surface ofeach of the enclosures 420 (e.g., along with periphery portions of thedies). The conductive paste 442 can be continuous along a verticaldirection and directly contact one or more bond pads 466 on devicesubstrate 464 that is connected to the dies. The conductive paste 442can provide an electrical connection between the one or more bond pads466 (that are, e.g., electrically connected to the electrical ground, asource voltage, a reference voltage or signal, etc.) and the enclosures420.

The conductive paste 442 can be isolated from active signals since theenclosures 420 act as barriers between the conductive paste 442 andinner/central portions of the dies and/or active surfaces thereof,internal connectors, or a combination thereof. Further the conductivepaste 442 can be isolated from active signals based on an underfillmaterial that is between the die stack and the device substrate 464 andencapsulates device interconnects that carry the active signals.

The conductive paste 442 can provide a high-current-capable ground pathfor the enclosures 420. Accordingly, the conductive paste 442 canprovide increase RF shielding along with the enclosures 420 and improvethe signal integrity (e.g., reduced interference and/or noise) of thesemiconductor device 400. Further, with the enclosures 420 acting asbarriers and physically separated from internal connectors, theenclosures 420 can further decrease the likelihood of failure due tounintended electrical shorts (e.g., such as due to misalignment ormisconnection, debris or bridges, etc.) between active signals, sourcevoltage, electrical ground, or a combination thereof.

FIG. 5 is a cross-sectional view of a semiconductor device 500 inaccordance with an embodiment of the present technology. Thesemiconductor device 500 can be similar to the semiconductor device 200of FIG. 2. For example, the semiconductor device 500 can includemultiple dies (e.g., such as for a die stack) with internalinterconnects providing electrical connections. Also for example, thesemiconductor device 500 can further include one or more metal enclosurestructures 520 (“enclosures 520”) between dies, between a die and adevice substrate, or a combination thereof with each enclosure enclosinga space (e.g., enclosed space) that includes the internal interconnects.The enclosed space can otherwise be vacuum or filled with inert orspecific gas. The internal interconnects, the enclosures 520, or acombination thereof can be electrically connected to (e.g., via directcontact or through a conductor) integrated circuits, bond pads, TSVs, ora combination thereof in or on the dies.

In some embodiments, the enclosures 520 can be connected to each other(e.g., ring-to-ring and/or enclosure-to-enclosure connection) through anouter-enclosure connector, such as bond wires 542. For example, asillustrated in FIG. 5, the semiconductor device 500 can have a bond wiredirectly contacting a periphery surface of one or more of the enclosures520. The bond wires 542 can further directly contact one or more bondpads 566 on device substrate 564 that is connected to the dies, andprovide an electrical connection between the one or more bond pads 566(e.g., for providing a connection to the electrical ground, a sourcevoltage, a reference voltage or signal, etc.) and the enclosures 520.Also for example, the semiconductor device 500 can have the bond wiresdirectly contacting and connecting the enclosures 520 (i.e., withoutgoing through the bond pads 566), such as daisy-chained wiring schemes.

The exposed periphery surface of the enclosures 520 can provide greatersurface area than a connection pad on the dies and/or bond pads thatcorrespond to active signals. As such, each of the enclosures 520 canconnect to multiple bond wires and/or thicker gauge wires to provide ahigh-current-capable ground path. Accordingly, the bond wires 542 andthe enclosures 520 can provide increase RF shielding and improve thesignal integrity (e.g., reduced interference and/or noise) of thesemiconductor device 500.

FIG. 6 is a cross-sectional view of a semiconductor device 600 inaccordance with an embodiment of the present technology. Thesemiconductor device 600 can be similar to the semiconductor device 200of FIG. 2. For example, the semiconductor device 600 can includemultiple dies, such as arranged in multiple stacks. The semiconductordevice 600 can include a first die stack 602 and a second die stack 604.Each die stack can include multiple dies with internal interconnectsproviding electrical connections.

Also for example, one or more stacks (e.g., the first die stack 602and/or the second die stack 604) of the semiconductor device 600 canfurther include multiple metal enclosure structures 620 (“enclosures620”) between dies, between a die and a device substrate, or acombination thereof with each enclosure enclosing a space (e.g.,enclosed space) that includes the internal interconnects. The enclosedspace can otherwise be vacuum or filled with inert or specific gas. Theinternal interconnects, the enclosures 620, or a combination thereof canbe electrically connected to (e.g., via direct contact or through aconductor) integrated circuits, bond pads, TSVs, or a combinationthereof in or on the dies.

In some embodiments, the enclosures 620 can be connected to each other(e.g., ring-to-ring and/or enclosure-to-enclosure connection, includingconnections within each die stack and/or across die stacks) through anouter-enclosure connector, such as a conductive paste 642 and/or bondwires 644. For example, as illustrated in FIG. 6, the semiconductordevice 600 can have the conductive paste 642 directly contacting aperiphery surface of each of the enclosures 620 (e.g., along withperiphery portions of the dies) for multiple die stacks. As illustratedin FIG. 6, the conductive paste 642 can be between the first die stack602 and the second die stack 604, directly contacting the enclosures 620in both the first die stack 602 and the second die stack 604. Theconductive paste 642 can provide electrical connection across theenclosures 620 of multiple die stacks. In some embodiments, theconductive paste 642 can further contact one or more bond pads 646 on adevice substrate 648 that is connected to the die stacks.

In some embodiments, the enclosures 620 can further be connected to eachother through the bond wires 644. One end of each of the bond wires 644can be directly attached to one of the enclosures 620. The opposing endof the bond wires 644 can be directly attached to one or more bond pads646. The bond pads 646 can provide a connection to the electricalground, a source voltage, a reference voltage or signal, etc. In someembodiments, one or more of the bond wires 644 can be used to directlycontact and connect the enclosures 620 across the first die stack 602and the second die stack 604. For example, the one or more of the bondwires 644 can extend along a horizontal direction between the first diestack 602 and the second die stack 604 and directly contact theenclosures thereof. Accordingly, the one or more of the bond wires 644can electrically connect the enclosures in the different die stacks,similarly as the conductive paste 642 illustrated in FIG. 6.

The conductive paste 642 directly contacting and electrically shortingthe enclosures 620 across multiple/adjacent die stacks can providehigh-current power or ground connection between the die stacks thatdoesn't pass through an interposer. For example, the conductive paste642 can bridge together the enclosures 620 across adjacent highbandwidth memory (HBM) stacks. The conductive paste 642 can provide ashorter path (e.g., in comparison to a path through other conductors orcircuitry). The shorter path can further eliminate ground loops thatinterfere with signal integrity for the semiconductor device 600.

FIG. 7 is a cross-sectional view of a semiconductor device in accordancewith an embodiment of the present technology. The semiconductor device700 can be similar to the semiconductor device 200 of FIG. 2. Forexample, the semiconductor device 700 can include multiple dies 702(e.g., such as for a die stack) with internal interconnects providingelectrical connections. Also for example, the semiconductor device 700can further include one or more metal enclosure structures 720(“enclosures 720”) between the dies 702, between a die and a devicesubstrate, or a combination thereof with each enclosure enclosing aspace (e.g., enclosed space) that includes the internal interconnects.The enclosed space can otherwise be vacuum or filled with inert orspecific gas. The internal interconnects, the enclosures 720, or acombination thereof can be electrically connected to (e.g., via directcontact or through a conductor) integrated circuits, bond pads, TSVs, ora combination thereof in or on the dies.

In some embodiments, the enclosures 720 can be further connected to eachother (e.g., ring-to-ring and/or enclosure-to-enclosure connection)through an outer-enclosure connector, such as a metal shield 742 (e.g.,an EMI or RF shield) and/or periphery TSVs 744. For example, asillustrated in FIG. 7, the semiconductor device 700 can have the metalshield 742 directly contacting, connected to (e.g., via solder,conductive paste, etc.), or integral with (e.g., via a diffusion bondingprocess) a periphery surface of one or more of the enclosures 720 (e.g.,along with periphery portions of the dies). The metal shield 742 canencompass or surround the dies (e.g., the die stack) over the devicesubstrate. Also for example, one or more of the dies in thesemiconductor device 700 can include the periphery TSVs 744 directlyconnected to the enclosures 720. When the rings are grounded (e.g.,through the periphery TSVs 744), the metal shield 742 can be groundedthrough the direct contact with the enclosures 720, eliminating any needfor an electrical connection between the metal shield 742 and a devicesubstrate.

FIGS. 8-9 are cross-sectional views illustrating a semiconductor deviceat selected stages in a manufacturing method in accordance with anembodiment of the present technology. As illustrated in FIG. 8, themethod can include a stage for providing a first die 802. The first die802 can include first-die interconnects 804 (e.g., solid metalstructures for providing electrical connections to circuits within thefirst die 802, such as for a portion of the internal interconnects)protruding below a first die bottom surface. The first die 802 canfurther include a first-die enclosure 810 (e.g., a solid metalstructure, such as for a portion of the metal enclosure structure)encircling a perimeter of the first die interconnects 804 along ahorizontal plane.

The first die 802 with the die interconnects 804 and the die enclosure806 can be manufactured using a separate manufacturing process (e.g.,wafer or die level manufacturing process). The separate manufacturingprocess can produce the die interconnects 804 and the die enclosure 806according to a protrusion measure 812 (e.g., a height of the metalstructures, such as a length measured between the die bottom surface anda distal portion of the die interconnects 804 and the die enclosure806). In some embodiments, the protrusion measure 812 can include adistance less than 20 μm. According to the protrusion measure 812, thedistal portions (e.g., relative to the die bottom surface) of the dieinterconnects 804 and the die enclosure 806 can be coplanar along ahorizontal plane that is parallel with the die bottom surface. In someembodiments, the separate manufacturing process can include forming oneor more TSVs (e.g., inner TSVs and/or periphery TSVs) directlycontacting the interconnects and/or the enclosure.

As illustrated in FIG. 9, the method can include a stage for providing asubstrate 906 (e.g., a PCB or another die, such as the second die, oneof the inner dies, etc.). The substrate 906 can include substrateinterconnects 904 (e.g., solid metal structures for providing electricalconnections to the substrate 906, such as for a portion of the internalinterconnects) protruding above a substrate top surface. The substrate906 can further include a substrate enclosure 910 (e.g., a solid metalstructure, such as for a portion of the metal enclosure structure)encircling a perimeter of the substrate interconnects 904 along ahorizontal plane.

The substrate 906 with the substrate interconnects 904 and the substrateenclosure 910 can be manufactured using a separate manufacturing process(e.g., wafer or die level manufacturing process or a process formanufacturing a printed circuit board). Similar to the stage illustratedin FIG. 8, the separate manufacturing process can produce the substrateinterconnects 904 and the substrate enclosure 910 according to aprotrusion measure 912 (e.g., a height of the metal structures, such asa length measured between the second boundary surface 224 and a distalportion of the substrate interconnects 904 and the substrate enclosure910). In some embodiments, the protrusion measure 912 can include adistance less than 20 μm. According to the protrusion measure 912, thedistal portions (e.g., relative to the substrate top surface) of thesubstrate interconnects 904 and the substrate enclosure 910 can becoplanar along a horizontal plane that is parallel with the substratetop surface. In some embodiments, the separate manufacturing process caninclude forming one or more TSVs (e.g., inner TSVs and/or peripheryTSVs) directly contacting the interconnects and/or the enclosure

As illustrated in FIG. 10, the method can include a stage for aligningthe substrate 906 and the die 802. The substrate 906 and the die 802 canbe aligned based on aligning reference portions (e.g., a center portion,a periphery edge or surface, etc.) thereof along a line or a plane(e.g., a vertical line or plane for FIG. 10). The structures can bealigned such that the die enclosure 810 and the substrate enclosure 910are aligned along a line or a plane (e.g., a vertical line or plane).Further, the structures can be aligned such that the die enclosure 810and the substrate enclosure 910 directly contact each other. The dieinterconnects 804 and the substrate interconnects 904 can be similarlyaligned.

As illustrated in FIG. 11, the method can include a stage for bondingthe metal structures (e.g., the die enclosure 810 to the substrateenclosure 910 and/or the die interconnects 804 to the substrateinterconnects 904). For example, FIG. 11 can represent a diffusionbonding process 1100 (e.g., Cu—Cu diffusion bonding) that includes asolid-state welding process (e.g., utilizing coalescence at temperaturesessentially below the melting point of the structures, with or withoutpressure/force pushing the structures together) for joining metals basedon solid-state diffusion. The diffusion bonding process 1100 can includecreating a vacuum condition or filling the space (e.g., the enclosedspace) with inert gas, heating the metal structures, pressing the metalstructures together, or a combination thereof.

Based on the bonding stage, the metal structures can bond or fuse andform a continuous structure. For example, the die enclosure 810 and thesubstrate enclosure 910 can be bonded to form the enclosures 220 of FIG.2, the enclosures 420 of FIG. 4, the enclosures 520 of FIG. 5, theenclosures 620 of FIG. 6, the enclosures 720 of FIG. 7, or a combinationthereof. Also for example, the die interconnects 804 and the substrateinterconnects 904 can be bonded to form the internal interconnects (suchas for 218 of FIG. 2).

Diffusion bonding the die enclosure 810 to the substrate enclosure 910(e.g., Cu—Cu diffusion bonding) and the die interconnects 804 and thesubstrate interconnects 904 (e.g., Cu—Cu diffusion bonding) providesreduced manufacturing failures and cost. The diffusion bonding processcan eliminate solder, thereby reducing any potential failures and costsassociated with the soldering process. Further, the interconnects andthe enclosures can be bonded using one bonding process, which canfurther simply the manufacturing process.

FIG. 12 is a flow diagram illustrating an example method 1200 (“method1200”) of manufacturing a semiconductor device in accordance with anembodiment of the present technology. For example, the method 1200 canbe implemented to manufacture the semiconductor device 200 of FIG. 2,the semiconductor device 300 of FIG. 3, the semiconductor device 400 ofFIG. 4, the semiconductor device 500 of FIG. 5, the semiconductor device600 of FIG. 6, and/or the semiconductor device 700 of FIG. 7. Also forexample, the method 1200 can include stages illustrated in FIGS. 8-11.

The method 1200 can include providing one or more semiconductor diestacks (e.g., the die stack 202 of FIG. 2, the die stack of FIG. 4, thedie stack of FIG. 5, the first die stack 602 of FIG. 6, the second diestack 604 of FIG. 6, the die stack of FIG. 7, etc.), such as the diestacks formed according to stages illustrated in FIGS. 8-11 (e.g.,semiconductor/wafer level processes, as illustrated in block 1220), asillustrated at block 1202. The one or more semiconductor die stacks caninclude multiple metal enclosures (e.g., the enclosures 220 of FIG. 2,the enclosures 420 of FIG. 4, the enclosures 520 of FIG. 5, theenclosures 620 of FIG. 6, the enclosures 720 of FIG. 7, etc.) disposedbetween multiple semiconductor dies (e.g., the top die, one or moremiddle dies, the bottom die, etc. as illustrated in FIGS. 2-7).

For example, the die stack can include a first metal enclosure thatdirectly contacts and vertically extend below from a bottom surface of atop die. The first metal enclosure can directly contact a top surface ofan adjacent die opposite the bottom surface of the top die. The diestack can further include a second metal enclosure that directlycontacts and vertically extend below from a bottom surface of theadjacent die, and further directly contacts a next adjacent die.

The enclosures in each of the stacks can encircle or surround internalinterconnects (e.g., conductors for communicating active signalsto/from/between dies). Each of the enclosures can further surround orenclose an enclosed space between a pair of dies. The enclosed spacescan be vacuum or a gas. Otherwise, the die stack can be without anyunderfill or encapsulation between the dies and/or within the enclosedspaces.

In some embodiments, the die stacks can include solder bumps (e.g.,device interconnects) attached to a bottom surface of a bottom die inthe die stack. In some embodiments, the die stacks can also includeunderfill directly on the bottom surface of the bottom die. Theunderfill can encompass the solder bumps.

The method 1200 can include providing a substrate (e.g., the devicesubstrate, such as a PCB, illustrated in FIG. 2 and/or FIGS. 4-7) asillustrated at block 1204. In some embodiment, providing the substratecan include manufacturing the substrate, such as based on formingtraces, vias, masks, etc., and/or based on attaching/connecting circuitcomponents to the substrate. In some embodiments, providing thesubstrate can include positioning and/or attaching to a frame forfurther processing.

The method 1200 can include attaching the structures as illustrated atblock 1206. For example, one or more die stacks can be attached to thesubstrate, such as based on reflowing the solder flows. For attachingmultiple die stacks to the substrate, the die stacks can be separated orspaced apart from each other along horizontal directions. Accordingly, agap or a separation space can be between a pair/set of die stacks.

The method 1200 can include electrically coupling the enclosures usingone or more enclosure connection mechanisms (e.g., the periphery TSVs242 of FIG. 2, the conductive paste 442 of FIG. 4 and 642 of FIG. 6, thebond wires 544 of FIG. 5, the metal shield 742 of FIG. 7, etc.) asillustrated at block 1208. For example, the enclosure connectionmechanism can directly contact and electrically couple together multipleenclosures within the die stack. Also for example, the enclosureconnection mechanism can directly contact and electrically coupletogether multiple enclosures across multiple die stacks.

In some embodiments, electrically coupling the enclosures can includeapplying a fillet of the conductive paste 442 to the enclosures asillustrated at block 1212. The conductive paste 442 can be applied as acontinuous fillet extending in a vertical direction and directlycontacting the metal enclosures within the die stack, such asillustrated in FIG. 4. The conductive paste 442 can also be applied tofill a space or a gap between a pair/set of die stacks, such that theconductive paste 442 directly contacts the metal enclosures acrossmultiple die stacks, such as illustrated in FIG. 6.

In some embodiments, electrically coupling the enclosures can includeattaching the bond wires 544 to the enclosures as illustrated at block1214. The bond wires 544 can be attached to the metal enclosures at oneend. Opposite the metal enclosures, the bond wires 544 can be attachedto one or more bond pads on the device substrate. In some embodiments,the bond wires 544 can each be connected to a pair of adjacentenclosures, such as for daisy-chained wiring schemes.

In some embodiments, electrically coupling the enclosures can includeattaching the metal shield 742 to the enclosures, the dies, and/or thedevice substrate as illustrated at block 1216. The metal shield 742 canbe placed or attached to surround the die stack and the dies therein.

In some embodiments, the metal shield 742 can directly contact the metalenclosures in the die stack. In some embodiments, the metal shield 742can be attached and/or integral with the enclosures. For example, themetal shield 742 can be attached to the enclosures using solder. Alsofor example, the metal shield 742 can be bonded to the metal enclosures,such as through a diffusion bonding process.

FIG. 13 is a flow diagram illustrating a further example method 1300(“method 1300”) of manufacturing a semiconductor device in accordancewith an embodiment of the present technology. For example, the method1300 can be implemented to manufacture one or more device stacks for thesemiconductor device 200 of FIG. 2, the semiconductor device 300 of FIG.3, the semiconductor device 400 of FIG. 4, the semiconductor device 500of FIG. 5, the semiconductor device 600 of FIG. 6, and/or thesemiconductor device 700 of FIG. 7. Also for example, the method 1300can include stages illustrated in FIGS. 8-11.

The method 1300 can include providing semiconductor dies as illustratedat block 1302. Providing the semiconductor die can correspond to thestage(s) illustrated in FIG. 8 and/or FIG. 9. The provided die caninclude die interconnects (e.g., the die interconnects 804 of FIG. 8,inter connects 904 of FIG. 9, etc.) and a die enclosure (e.g., the dieenclosure 810 of FIG. 8, enclosure 910 of FIG. 9, etc.) protrudingdownward from a die bottom surface. The die enclosure can peripherallysurround the die interconnects on or along the die bottom surface. Theprovided die can further have bottom or distal portions or surfaces ofthe die interconnects coplanar with bottom or distal portions orsurfaces of the die enclosure. For example, the bottom or distalportions of the die interconnects and the die enclosure can be coplanaralong a horizontal plane that is parallel to the die bottom surface andis vertically offset from the die bottom surface by a protrusionmeasure. In some embodiments the die enclosure can include copper,aluminum, nickel, other metals, or a combination thereof.

The die can be manufactured or formed using a separate manufacturingprocess, as illustrated at block 1320. For example, the diemanufacturing process can include wafer-level processing, such as adoping process to form integrated circuitry and a singulating process toseparate the individual dies. Also for example, the die manufacturingprocess can include electrically coupling the enclosures as illustratedat block 1350.

In some embodiments, electrically coupling the enclosures can includeforming one or more TSVs (e.g., the periphery TSVs 242 of FIG. 2 at aperiphery portion of the corresponding die). For example, the TSVs canbe formed based on lithography or etching, masking or depositing seedlayer, plating, back-side processing, or a combination thereof.

In some embodiments, electrically coupling the enclosures can alsoinclude forming the enclosure rings (e.g., die enclosure) connected toone or more of the TSVs. For example, the enclosure rings can be formeddirectly contacting or integral with the periphery TSVs 242. Theenclosure rings can be formed using a process similar to the TSVs.

The method 1300 can include aligning the structures as illustrated atblock 1304 (e.g., the dies and the metal enclosures). Aligning thestructures can correspond to the stage illustrated in FIG. 10. Forexample, the alignment process can align the dies over the substratewith a portion of each die interconnect coincident with a correspondingportion of each substrate interconnect along vertical lines and/or aportion of the die enclosure coincident with the substrate enclosurealong vertical lines. Also for example, the alignment process can alignthe die over the substrate with the die enclosure directly contactingthe substrate enclosure.

The method 1300 can further include bonding the structures (e.g., thedie interconnects to the substrate interconnects and/or the dieenclosure to the substrate enclosure) as illustrated at block 1306. Thebonding process can correspond to the stage illustrated in FIG. 11. Thebonding process can include controlling temperature of one or more ofthe structures (e.g., heating to bond and then cooling to solidify thejointed structures), applying pressure on the structures, or acombination thereof. For example, the bonding process can includediffusion bonding (e.g., thermal compression bonding or TCB) asillustrated at block 1312.

Through the bonding process, the enclosures and the enclosed spaces canform. Since metal (e.g., copper, solder, etc.) sufficiently blocksmoisture and other debris, underfill is no longer needed for themanufacturing process. As such, the bonding process can bond thestructures without any underfill in the enclosed spaces. Further, theabove described bonding process can eliminate oxide to oxide bonding(e.g., for hybrid bonding) and/or the requirement on wafer surfaceconditions (e.g., surface roughness control), which can lead to lowermanufacturing cost and error.

In some embodiments, solder bumps can be added to a bottom surface ofthe bonded structure (e.g., the die stack). In some embodiments,underfill can be applied to the bottom surface of the die stack.

FIG. 14 is a block diagram illustrating a system that incorporates asemiconductor device in accordance with embodiments of the presenttechnology. Any one of the semiconductor devices having the featuresdescribed above with reference to FIGS. 2-13 can be incorporated intoany of a myriad of larger and/or more complex systems, a representativeexample of which is system 1490 shown schematically in FIG. 14. Thesystem 1490 can include a processor 1492, a memory 1494 (e.g., SRAM,DRAM, flash, and/or other memory devices), input/output devices 1496,and/or other subsystems or components 1498. The semiconductorassemblies, devices, and device packages described above with referenceto FIGS. 2-13 can be included in any of the elements shown in FIG. 14.The resulting system 1490 can be configured to perform any of a widevariety of suitable computing, processing, storage, sensing, imaging,and/or other functions. Accordingly, representative examples of thesystem 1490 include, without limitation, computers and/or other dataprocessors, such as desktop computers, laptop computers, Internetappliances, hand-held devices (e.g., palm-top computers, wearablecomputers, cellular or mobile phones, personal digital assistants, musicplayers, etc.), tablets, multi-processor systems, processor-based orprogrammable consumer electronics, network computers, and minicomputers.Additional representative examples of the system 1490 include lights,cameras, vehicles, etc. With regard to these and other examples, thesystem 1490 can be housed in a single unit or distributed over multipleinterconnected units, e.g., through a communication network. Thecomponents of the system 1490 can accordingly include local and/orremote memory storage devices and any of a wide variety of suitablecomputer-readable media.

From the foregoing, it will be appreciated that specific embodiments ofthe present technology have been described herein for purposes ofillustration, but that various modifications may be made withoutdeviating from the disclosure. In addition, certain aspects of thedisclosure described in the context of particular embodiments may becombined or eliminated in other embodiments. Further, while advantagesassociated with certain embodiments have been described in the contextof those embodiments, other embodiments may also exhibit suchadvantages. Not all embodiments need necessarily exhibit such advantagesto fall within the scope of the present disclosure. Accordingly, thedisclosure and associated technology can encompass other embodiments notexpressly shown or described herein.

We claim:
 1. A semiconductor device, comprising: a first die; a firstmetal enclosure directly contacting and vertically extending below thefirst die, wherein the first metal enclosure peripherally encircles afirst enclosed space; a second die directly contacting the first metalenclosure opposite the first die; a second metal enclosure directlycontacting and vertically extending below the second die, wherein thesecond metal enclosure peripherally encircles a second enclosed space;an enclosure connection mechanism directly contacting the first metalenclosure and the second metal enclosure for electrically coupling thefirst metal enclosure and the second metal enclosure, wherein theenclosure connection mechanism includes: a first connection directlyconnected to the first metal enclosure, and a second connection directlyconnected to the second metal enclosure; and a pad directly connected tothe first connection and the second connection opposite the first metalenclosure and the second metal enclosure, respectively, wherein the padis configured to provide an electrical connection to the firstconnection and the second connection.
 2. The semiconductor device ofclaim 1, wherein the enclosure connection mechanism includes one or morethrough-silicon vias (TSVs) extending vertically through the second die.3. The semiconductor device of claim 1, wherein the enclosure connectionmechanism includes conductive paste.
 4. The semiconductor device ofclaim 3, wherein: the conductive paste is continuous along a verticaldirection; and further comprising: a pad directly contacting theconductive paste, wherein the pad is configured to provide an electricalconnection to the conductive paste.
 5. The semiconductor device of claim3, further comprising: a first die stack including the first die, thefirst metal enclosure, the second die, and the second metal enclosure; asecond die stack separated from the first die stack along a horizontalplane, the second die stack including a third metal enclosure between apair of dies; and wherein: the conductive paste directly contacts thethird metal enclosure for electrically coupling the first metalenclosure and/or the second metal enclosure with the third metalenclosure along a horizontal direction and for electrically couplingacross the first die stack and the second die stack.
 6. Thesemiconductor device of claim 1, wherein the first and secondconnections include bond wires.
 7. The semiconductor device of claim 1,wherein the enclosure connection mechanism includes a metal shieldsurrounding the first die and the second die, wherein the metal shielddirectly contacts or is integral with the first metal enclosure and thesecond metal enclosure.
 8. The semiconductor device of claim 7, whereinthe metal shield comprises a radio-frequency (RF) shield or anelectromagnetic interference (EMI) shield.
 9. The semiconductor deviceof claim 1, wherein the enclosure connection mechanism is configured toelectrically couple the first metal enclosure and the second metalenclosure to an electrical ground.
 10. The semiconductor device of claim1, wherein: the first die includes a first-die periphery surface; thesecond die include a second-die periphery surface; the first metalenclosure includes a first-enclosure periphery surface; the second metalenclosure includes a second-enclosure periphery surface; and thefirst-die periphery surface, the second-die periphery surface, thefirst-enclosure periphery surface, and the second-enclosure peripherysurface form a continuous periphery surface.
 11. The semiconductordevice of claim 10, wherein one or more points or portions on each ofthe first-die periphery surface, the second-die periphery surface, thefirst-enclosure periphery surface, and the second-enclosure peripherysurface are coincident along a vertical line.
 12. The semiconductordevice of claim 10, wherein: the first-die periphery surface and thesecond-die periphery surface are aligned and coincident along a verticalline; and the first-enclosure periphery surface and the second-enclosureperiphery surface are offset from the vertical line toward centerportions of the first die and the second die, wherein thefirst-enclosure periphery surface and the second-enclosure peripherysurface are offset by an edge offset distance from the first-dieperiphery surface and the second-die periphery surface.
 13. Thesemiconductor device of claim 1, wherein the semiconductor device is athree dimensional interconnect (3DI) device.
 14. The semiconductordevice of claim 1, wherein: the first die, the first metal enclosure,the second die, and the second metal enclosure comprise a die stack; andfurther comprising: device interconnects attached to a bottom surface ofthe die stack; a device substrate attached to the device interconnectsopposite the die stack.
 15. A semiconductor device including a diestack, comprising: a first metal sealing member disposed between a pairof adjacent dies in the die stack, wherein the first metal sealingmember encloses a first set of a plurality of interconnects; a secondmetal sealing member below the pair of adjacent dies, wherein the secondmetal sealing member encloses a second set of a plurality ofinterconnects; and an enclosure connection mechanism directly contactingthe first metal enclosure and the second metal enclosure forelectrically coupling the first metal enclosure and the second metalenclosure that are vertically separated with one or more dies therebetween.
 16. The semiconductor device of claim 15, wherein the enclosureconnection mechanism includes one or more through-silicon vias (TSVs)extending vertically through the one or more dies.
 17. The semiconductordevice of claim 15, wherein the enclosure connection mechanism includesone or more bond wires.
 18. The semiconductor device of claim 17,wherein the enclosure connection mechanism includes: a first bond wiredirectly connected to the first metal sealing member; a second bond wiredirectly connected to the second metal sealing member; and furthercomprising: a pad directly connected to the first bond wire and thesecond bond wire opposite the first metal sealing member and the secondmetal sealing member, respectively, wherein the pad is configured toprovide an electrical connection to the first bond wire and the secondbond wire.
 19. The semiconductor device of claim 15, wherein: theenclosure connection mechanism includes conductive paste continuousalong a vertical direction; and further comprising: a pad directlycontacting the conductive paste, wherein the pad is configured toprovide an electrical connection to the conductive paste.
 20. Asemiconductor device, comprising: a first die; a first metal enclosuredirectly contacting and vertically extending below the first die,wherein the first metal enclosure peripherally encircles a firstenclosed space along a first horizontal plane; a second die directlycontacting the first metal enclosure opposite the first die; a secondmetal enclosure directly contacting and vertically extending below thesecond die, wherein the second metal enclosure peripherally encircles asecond enclosed space along a second horizontal plane; an enclosureconnection mechanism directly contacting the first metal enclosure andthe second metal enclosure for electrically coupling the first metalenclosure and the second metal enclosure.